Termitarium volume as a determinant of invasion by obligatory termitophiles and inquilines in the nests of Constrictotermes cyphergaster (Termitidae, Nasutitermitinae)

A range of organisms can be found inside termite nests where the degree of association can vary from facultative to obligatory dependence. Studies of the dynamics of nest invasion are still unresolved, so how and when cohabitants enter termite nests remain open questions. This study analyzed one specific aspect of the dynamics of termite nest invasion by obligatory termitophiles and inquilines, i.e., whether cohabitants were more likely to invade a nest when it reached a critical nest size. We collected 36 Constrictotermes cyphergaster nests of different sizes and sampled their cohabitant fauna. Our results indicated that the invasion of C. cyphergaster nests by obligatory termitophiles and inquilines was dependent on nest size. There appeared to be a critical nest size above which nests were more prone to invasion. Above this size, there was a significantly higher likelihood of finding obligatory cohabitants. Termitophile species were observed in nests ≥2.2?L, whereas inquiline species were only occur in nests ≥13.6?L. This may indicate that the obligatory cohabitants studied here did not occupy C. cyphergaster nests at random and that they were dependent on features that made these nests suitable for cohabitation, which are linked to colony development.     

Alignment-free prediction of mycobacterial DNA promoters based on pseudo-folding lattice network or star-graph topological indices

The importance of the promoter sequences in the function regulation of several important mycobacterial pathogens creates the necessity to design simple and fast theoretical models that can predict them. This work proposes two DNA promoter QSAR models based on pseudo-folding lattice network (LN) and star-graphs (SG) topological indices. In addition, a comparative study with the previous RNA electrostatic parameters of thermodynamically-driven secondary structure folding representations has been carried out. The best model of this work was obtained with only two LN stochastic electrostatic potentials and it is characterized by accuracy, selectivity and specificity of 90.87%, 82.96% and 92.95%, respectively. In addition, we pointed out the SG result dependence on the DNA sequence codification and we proposed a QSAR model based on codons and only three SG spectral moments.     

Characterization of an Alcohol Dehydrogenase from the Cyanobacterium Synechocystis sp. Strain PCC 6803 That Responds to Environmental Stress Conditions via the Hik34-Rre1 Two-Component System

The slr1192 (adhA) gene from Synechocystis sp. strain PCC 6803 encodes a member of the medium-chain alcohol dehydrogenase/reductase family. The gene product AdhA exhibits NADP-dependent alcohol dehydrogenase activity, acting on a broad variety of aromatic and aliphatic primary alcohols and aldehydes but not on secondary alcohols or ketones. It exhibits superior catalytic efficiency for aldehyde reduction compared to that for alcohol oxidation. The enzyme is a cytosolic protein present in photoautotrophically grown Synechocystis cells. The expression of AdhA is enhanced upon the exposure of cells to different environmental stresses, although it is not essential for survival even under such stress conditions. The induction of the expression of the adhA gene is dependent on the Hik34-Rre1 two-component system, as it is severely impaired in mutant strains lacking either the histidine kinase Hik34 or the response regulator Rre1. In vitro DNA-protein interaction analysis reveals that the response regulator Rre1 binds specifically to the promoter region of the adhA gene.Medium-chain dehydrogenases/reductases (MDR) constitute a superfamily of alcohol dehydrogenases that catalyze the reversible NAD(P)-dependent oxidation of alcohols to aldehydes or ketones. It includes a large number of structurally related proteins, which catalyze several types of enzymatic activity (23, 41, 44). Screening of complete genome sequences has revealed that this family is widespread, complex, and of ancient origin (22, 44). MDR alcohol dehydrogenases are found in mammals, plants, fungi, and bacteria (52). The alcohol dehydrogenases fulfill an astonishing variety of functions in cell metabolism (21), also being a key enzyme in ethanol generation by Saccharomyces cerevisiae (6) and bacteria (10). Furthermore, the generation of biofuels by photoautotrophic microorganisms is of great biotechnological interest (43). Complementation of a cyanobacterium''s enzyme machinery with a specific exogenous gene(s) can result in the ability to generate bioethanol from photosynthetically fixed CO₂ (11). Notwithstanding, current knowledge of cyanobacterial alcohol dehydrogenases is rather limited. In the cyanobacterium Synechocystis sp. strain PCC 6803 (referred here as Synechocystis), the slr1192 gene encodes a putative MDR alcohol dehydrogenase. According to in silico analyses (38, 44), the slr1192 protein has similarity with two subfamilies of MDRs: the yeast ADH family (Y-ADH) and the cinnamyl ADH family (CADH). Y-ADH-related enzymes have catabolic functions and are involved mainly in the metabolism of ethanol or short-chain alcohols for which they exhibit broad substrate specificity. CADH and related enzymes, on the other hand, perform anabolic functions and participate in biosynthetic pathways in plants and bacteria (5, 25, 44).In Synechocystis, the expression of slr1192 is induced by osmotic (35) or salt (48) stress. In higher plants, alcohol dehydrogenase activity appears to be involved in aerobic metabolism under certain stress conditions (26, 56) such as low temperature, water deficit, or ozone exposure, but its function remains unknown. A temperature decrease seems to induce the accumulation of alcohol dehydrogenase mRNA in Arabidopsis thaliana (20), corn, and rice (9).In general, cyanobacteria perceive and respond to environmental changes by means of two-component regulatory systems, a ubiquitous signal transduction pathway that represents a prevalent signaling mechanism in bacteria (8, 61). Two-component systems consist of a histidine kinase (Hik) and a response regulator (Rre) and generally induce or repress the expression of specific genes in response to environmental stimuli. The histidine kinase autophosphorylates a conserved histidine residue in response to the environmental signal and then transfers the phosphate group to a conserved aspartate residue of the response regulator, which mediates the transfer of the signal. In Synechocystis, different Hik-Rre systems have been identified as being regulators of the response to different environmental stresses (37). A membrane-bound histidine kinase, Hik33, is involved in the perception of cold, salt, and osmotic stress (33, 35, 39, 48, 54). A cytosolic histidine kinase, Hik34, has been shown to be involved in the perception of salt and hyperosmotic stress (33, 39, 48) as well as heat shock (53). Specifically, the couples Hik33-Rre31, Hik10-Rre13, Hik16 Hik41-Rre17, Hik34-Rre1, and a putative Hik2-Rre1 have been identified as being elements involved in the perception and transduction of signals promoted by hyperosmotic and salt stress (39, 48).In the present work, a biochemical characterization of the slr1192 protein (designated AdhA here) from Synechocystis has been performed, revealing that the tetrameric 140-kDa enzyme is active toward linear and aromatic primary alcohols and that it preferentially reduces aldehydes rather than oxidizing alcohols. In addition, an extensive analysis of the expression of the adhA gene has verified its induction in response to heat shock, hyperosmotic stress, salt stress, and the addition of benzyl alcohol (BA). The Hik34-Rre1 two-component system has been shown to play a relevant role in the regulation of the expression of the adhA gene under these stress conditions. A specific interaction of Rre1 with the promoter region of the adhA gene has also been demonstrated. In light of this finding and additional information presented here, the physiological role of AdhA in Synechocystis is discussed.     

Overoxidation of 2-Cys Peroxiredoxin in Prokaryotes: CYANOBACTERIAL 2-CYS PEROXIREDOXINS SENSITIVE TO OXIDATIVE STRESS*?

In eukaryotic organisms, hydrogen peroxide has a dual effect; it is potentially toxic for the cell but also has an important signaling activity. According to the previously proposed floodgate hypothesis, the signaling activity of hydrogen peroxide in eukaryotes requires a transient increase in its concentration, which is due to the inactivation by overoxidation of 2-Cys peroxiredoxin (2-Cys Prx). Sensitivity to overoxidation depends on the structural GGLG and YF motifs present in eukaryotic 2-Cys Prxs and is believed to be absent from prokaryotic enzymes, thus representing a paradoxical gain of function exclusive to eukaryotic organisms. Here we show that 2-Cys Prxs from several prokaryotic organisms, including cyanobacteria, contain the GG(L/V/I)G and YF motifs characteristic of sensitive enzymes. In search of the existence of overoxidation-sensitive 2-Cys Prxs in prokaryotes, we have analyzed the sensitivity to overoxidation of 2-Cys Prxs from two cyanobacterial strains, Anabaena sp. PCC7120 and Synechocystis sp. PCC6803. In vitro analysis of wild type and mutant variants of the Anabaena 2-Cys Prx showed that this enzyme is overoxidized at the peroxidatic cysteine residue, thus constituting an exception among prokaryotes. Moreover, the 2-Cys Prx from Anabaena is readily and reversibly overoxidized in vivo in response to high light and hydrogen peroxide, showing higher sensitivity to overoxidation than the Synechocystis enzyme. These cyanobacterial strains have different strategies to cope with hydrogen peroxide. While Synechocystis has low content of less sensitive 2-Cys Prx and high catalase activity, Anabaena contains abundant and sensitive 2-Cys Prx, but low catalase activity, which is remarkably similar to the chloroplast system.     

Quantitative global studies of reactomes and metabolomes using a vectorial representation of reactions and chemical compounds

Background  

Global studies of the protein repertories of organisms are providing important information on the characteristics of the protein space. Many of these studies entail classification of the protein repertory on the basis of structure and/or sequence similarities. The situation is different for metabolism. Because there is no good way of measuring similarities between chemical reactions, there is a barrier to the development of global classifications of "metabolic space" and subsequent studies comparable to those done for protein sequences and structures.     

Selecting thioredoxins for disulphide proteomics: target proteomes of three thioredoxins from the cyanobacterium Synechocystis sp. PCC 6803

Searching for enzymes and other proteins which can be redox-regulated by dithiol/disulphide exchange is a rapidly expanding area of functional proteomics. Recently, several experimental approaches using thioredoxins have been developed for this purpose. Thioredoxins comprise a large family of redox-active enzymes capable of reducing protein disulphides to cysteines and of participating in a variety of processes, such as enzyme modulation, donation of reducing equivalents and signal transduction. In this study we screened the target proteomes of three different thioredoxins from the unicellular cyanobacterium Synechocystis sp. PCC 6803, using site-directed active-site cysteine-to-serine mutants of its m-, x- and y-type thioredoxins. The properties of a thioredoxin that determine the outcome of such analyses were found to be target-binding capacity, solubility and the presence of non-active-site cysteines. Thus, we explored how the choice of thioredoxin affects the target proteomes and we conclude that the m-type thioredoxin, TrxA, is by far the most useful for screening of disulphide proteomes. Furthermore, we improved the resolution of target proteins on non-reducing/reducing 2-DE, leading to the identification of 14 new potentially redox-regulated proteins in this organism. The presence of glycogen phosphorylase among the newly identified targets suggests that glycogen breakdown is redox-regulated in addition to glycogen synthesis.     

Tempo and mode of early gene loss in endosymbiotic bacteria from insects

Background  

Understanding evolutionary processes that drive genome reduction requires determining the tempo (rate) and the mode (size and types of deletions) of gene losses. In this study, we analysed five endosymbiotic genome sequences of the gamma-proteobacteria (three different Buchnera aphidicola strains, Wigglesworthia glossinidia, Blochmannia floridanus) to test if gene loss could be driven by the selective importance of genes. We used a parsimony method to reconstruct a minimal ancestral genome of insect endosymbionts and quantified gene loss along the branches of the phylogenetic tree. To evaluate the selective or functional importance of genes, we used a parameter that measures the level of adaptive codon bias in E. coli (i.e. codon adaptive index, or CAI), and also estimates of evolutionary rates (Ka) between pairs of orthologs either in free-living bacteria or in pairs of symbionts.     

Fluorescence study of ligand binding to potato tuber pyrophosphate-dependent phosphofructokinase: evidence for competitive binding between fructose-1,6-bisphosphate and fructose-2,6-bisphosphate

The intrinsic fluorescence of potato tuber pyrophosphate:fructose-6-phosphate 1-phosphotransferase (PFP) was used as an indicator of conformational changes due to ligand binding. Binding of the substrates and the allosteric activator fructose-2,6-bisphosphate was quantitatively compared to their respective kinetic effects on enzymatic activity. PFP exhibited a relatively high affinity for its isolated substrates, relative to the enzyme's respective K(m) (substrate) values. There are two distinct types of fructose-1,6-bisphosphate interaction with PFP, corresponding to catalytic and activatory binding. Activatory fructose-1,6-bisphosphate binding shares several characteristics with fructose-2,6-bisphosphate binding, indicating that both ligands compete for the same allosteric activator site. Activation by fructose-1,6-bisphosphate or fructose-2,6-bisphosphate was exerted primarily on the forward (glycolytic) reaction by greatly increasing the enzyme's affinity for fructose-6-phosphate. Binding of substrates and effectors to PFP and PFP kinetic properties were markedly influenced by assay pH. Results indicate an increased glycolytic role for PFP during cytosolic acidification that accompanies anoxia stress.